<p> I-1</p><p>Electric Currents and Simple Circuits</p><p>Electrons can flow along inside a metal wire if there is an E-field present to push them along (   F= q E ). The flow of electrons in a wire is similar to the flow of water in a pipe.</p><p>DQ Definition: electric current I = = rate of flow of charge Dt units [ I ] = coulomb/second = 1 C / 1 s = 1 ampere (A) = "amp"</p><p>"It's not the voltage that kills you, it the amps." About 0.05 A is enough to kill you. If current I = 1 A in a wire, then 1 coulomb of charge flows past any point every second. </p><p>I</p><p> In electrostatic problems, E= 0 inside a metal, but if I  0, then the situation is not static, the E-field is not zero. Electrons flow in metals, not protons, so (–) charges are moving when there is a current. The r r electron feel a force F= - e E and goes E "upstream" against the E-field.</p><p>The flow of (–) charge in one direction is electrically equivalent to the flow of (+) charge in the opposite direction:</p><p> neutral either way, + + + + () or (+) plates get:    </p><p>Last update: 4/4/2018 Dubson Phys2020 Notes, University of Colorado I-2</p><p>By convention, we define current I as the flow of imaginary (+) charges, when it is really (–) charges flowing the other way: </p><p>I</p><p>(Some texts refer to I as the "conventional current" to distinguish it from the "electron current".)</p><p>Example: How many electrons flow past per second when the current is 1 A? </p><p>DQ D N譊 e N I 1 A 1C / s 18- 1 I= =� = =-19 = - 19 5.6 10 s Dt D t D t e 1.6创 10 C 1.6 10 C</p><p>About 0.01 A = 10 mA flowing though your heart is lethal, yet I could grab a wire carrying 1000A and be safe! Why? Because my body has a much higher electrical resistance than the metal. The electrons prefer to flow through the metal wire.</p><p>For most materials, the current I is proportional to the voltage difference between the ends. r r I礑 E (since F = q E) and V 档 E, so I D V</p><p> hi V lo V E I</p><p>V From now on, we usually follow the (bad) convention and write "V" when we really mean "V". V I档 V ( really I D V)� constant I V Definition of resistance R (of a piece of wire or other material): R I The experimental fact that (for most materials) the ratio R = V / I is a constant, independent of V or I, is called V Ohm's Law : R= = constant , usually written V = I R (R constant) I Units: [R] = volt / ampere = ohm () ["" is Greek letter omega]</p><p>Last update: 4/4/2018 Dubson Phys2020 Notes, University of Colorado I-3</p><p>Ohm's Law should be written V = I R, but the bad convention is to write V = I R. "Ohm's Law" is not really a law, because it is not always true. For many materials, Ohm's Law is approximately true, the resistance R is approximately constant, independent of V or I. Materials that obey Ohm's Law are called "ohmic materials". But some materials are "non- ohmic"; they do not obey Ohm's Law. </p><p>The average speed of electrons in a current-carrying wire results from a competition between two r r r effects: (1) the E-field, which causes an acceleration according to F= q E = m a , making the electrons go faster and faster, and (2) the scattering of electrons due to impurities and thermal vibrations, which act like friction, making the electrons slow down.</p><p>For typical currents in real wires, the average electron speed (often called the drift velocity) is actually quite slow, typically less than 0.1 mm/s. (Incidentally, the term drift velocity is incorrect, it should be called the drift speed.)</p><p>A material with lots of electron scattering has a high resistance:</p><p>5 Rwire << 1 , Rhuman  10  </p><p>V 10V - 4 I= =5 = 10 A (harmless) R 10 W  10 V safe, 100 V dangerous ! V 100V - 3 I= =5 = 10 A (painful!) R 10 W</p><p>The resistance R of a piece of material depends on its shape and composition. Shape: long and skinny  R big </p><p> short and fat  R small </p><p>— just like the flow of water through a pipe. Long skinny water pipes resist flow of water. L Turns out that R , L A area A so big L means big R, big A means small R</p><p>Last update: 4/4/2018 Dubson Phys2020 Notes, University of Colorado I-4</p><p> r L R =  (Greek letter "rho") = resistivity A ( We show were this comes in the next section below.) Resistivity  depends on the material composition, not on the shape.  is a measure of the scattering of electrons in that material, like viscosity of fluid in a pipe. Big  means lots of scattering (friction), big resistance to flow. A r = R Units: {L [  ] = [R]  length = m length length length material  use Cu 1.7  10-8 m house wiring Al 2.7  10-8 m power lines W (tungsten) 5.3  10-8 m (cool) light bulb filaments 60  10-8 m (hot) Fe 9.8  10-8 m not used in wiring glass 10+10 m electrical insulator</p><p>Microscopic view of Ohm's Law. I Definition: current density J = (current per area in a conductor). We also define current A density vector J where direction of J is the direction of the current.</p><p>J is related to the average speed vdrift of the charge carriers (usually electrons) by </p><p>J = n q vdrift ,</p><p> n is the number of carrier per volume, q is the charge per carrier (usually q = e). Proof: Consider a wire with carrier density n (#/volume), cross-sectional area A, and drift speed </p><p> vdrift. In a time t, all the charges move an average distance x = vdrift t.</p><p> area A volume = A  x</p><p>J</p><p>x = v t Last update: 4/4/2018 Dubson Phys2020 Notes, Universitydrift of Colorado I-5</p><p>The charge Q in the length of wire x is </p><p> number of carriers charge DQ= 创 volume = n q A D x volume carrier</p><p>ID Q 1 n q A D x So the current density is J= =� = n q vdrift Done. AD t A A D t</p><p>In ohmic materials, the current density J is proportional to the electric field E v v J= s E , where the proportionality constant  is called the conductivity. 1 The resistivity  is defined as r = and so E =  J. s J= s E or E= r J , where  = 1/ = constant is the microscopic version of Ohm's Law. We now show that this is equivalent to V = I R : Consider a cylindrical section of conductor, length L, cross-sectional area A, with current density J, and E-field E.</p><p>Start with E= r J , now multiply both sides by L and write </p><p>A J, E I J as J = I / A.  E L= r L . Notice that V = E L. A L r L So we have DV= I , or DV= I R , where we A</p><p> r L have defined the resistance R as R = . We have just shown that E= r J is the same as A</p><p> r L Ohm's Law V = I R, where R = . A</p><p>Last update: 4/4/2018 Dubson Phys2020 Notes, University of Colorado I-6</p><p>A Simple Circuit Some electrical circuits symbols:</p><p>R C resistor capacitor</p><p> switch battery E or V</p><p>(–) side (+) side</p><p>A battery's job is to maintain a constant voltage difference between its terminals. It acts like a charge pump, pushing (+) charge inside the battery from the (–) side to the (+) side. This is the direction that the charges don't want to go. The battery has to do chemical work to push the charges "uphill" (toward higher electrostatic PE).</p><p>"10-volt battery" means voltage across battery = E or V (or just V) = 10 volts = 10 V. Hence the confusing equation: V = 10 V, meaning "the voltage difference across battery is 10 volts".</p><p> switch open switch closed V = +10V V = +10V R = 50  V battery I R (carbon V = 0V resistor) wire V = 0V</p><p>Always assume that the wires connecting circuit elements have zero resistance Rwire = 0  no voltage change along the wire, since Vwire = I Rwire = I  0 = 0.</p><p>V 10V Current around the circuit is: I= = = 0.2A R 50W</p><p>Recall that (+) charge tends toward low voltage. Can think of voltage as a kind of "electrical pressure". Water in a pipe flows from high pressure to low pressure. Likewise, (+) charges in a wire flow from hi V to lo V. In the water-pipe analogy, we can think of a resistor as like a porous plug of gravel in the pipe. The gravel plug offers resistance to the flow of water, so we need a large pressure difference to push the water through.</p><p>Last update: 4/4/2018 Dubson Phys2020 Notes, University of Colorado I-7</p><p>If no pressure difference across a pipe plug, then no water flows. If no voltage difference across a resistor, then no current flows. I flow hi V lo V hi P lo P</p><p> gravel plug in water-filled V = V = I R pipe Inside a resistor, (+) charge flows from hi V  lo V ("downhill") Inside a battery, (+) charge flows from lo V  hi V ("uphill"). Current I is the same in the battery and the resistor, just as water flow (in gallons per minute) is same through pump and through gravel plug.</p><p> hi pressure hi V</p><p>Pump gravel V I R </p><p> lo pressure lo V</p><p>Electrical Power When I is big, R gets hot because the flowing electrons are scattered  friction. Recall that power P = rate at which energy is transformed = rate at which work is done</p><p>W joule P D , [ P]= = 1 watt (W) Dt second</p><p>In a resistor, the rate at which electrostatic PE is converted into thermal energy (heat) is P = I V ( really, P = I V )</p><p>If I = constant, then the average speed of electrons is constant  KE = (1/2)mv2 = constant.</p><p>Last update: 4/4/2018 Dubson Phys2020 Notes, University of Colorado I-8</p><p>When an amount of charge Q flows through a resistor in a time t, from the high V side to the low V side, the change in PE of that charge is PE = Q V. The PE of the charge Q is decreased, but KE = constant. Where did the energy go? Answer: into thermal energy PE骣 Q P=D =譊 V = I V 桫 { t{ t V I</p><p>P = I V and V = I R  P = I ( I R ) = I2 R or P = (V / R) V = V2 / R V2 3 equivalent expressions for power: P= I V = I2 R = R</p><p>"100 W bulb" uses P = 100 W. Light bulbs and most other appliances (TV, coffee grinder) are designed to work with voltage V = 120 V (really V = 120 V). example of electrical power: What is the current through a 100 W light bulb? What is its resistance (when on and hot).</p><p>2 P 100 W V2 V 2 (120V) I= = = 0.83A , P=� R = = W 144 V 120V R P 100 W</p><p>Last update: 4/4/2018 Dubson Phys2020 Notes, University of Colorado </p>